Aerodynamics and Aeroacoustics of Vehicles, Volume II

A special issue of Fluids (ISSN 2311-5521).

Deadline for manuscript submissions: closed (30 June 2022) | Viewed by 26914

Special Issue Editor


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Guest Editor
1. Professor, Department of Mechanical Engineering & Engineering Science, The University of North Carolina at Charlotte, Charlotte, NC 28228-0001, USA
2. Coordinator, Digital Design Optimization Initiative, The University of North Carolina at Charlotte, Charlotte, NC 28228-0001, USA
3. Chair, SAE Road Vehicles Aerodynamics Committee, Warrendale, PA, USA
Interests: race and street car aerodynamics; aerodynamics and aeroacoustics of passenger and commercial vehicles; experimental and computational study of jets, wakes, and boundary layer flows; flow separation and control; aerodynamics of small aerial vehicles; shock–boundary layer interactions; data-driven turbulence modeling; machine learning methods in fluid flow classification
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Special Issue Information

Dear Colleagues,

Aerodynamics is one of the major factors to consider during the design and development phases of vehicles, be they passenger or commercial road vehicles, race cars, trains, or air vehicles. During the early days of vehicle aerodynamics, improved fuel economy and speed gain by drag reduction, and improving occupant safety and comfort by minimizing the effects of aerodynamic instability were the major goals of vehicle aerodynamics. However, as ground vehicles became faster and high-speed road and train transportation infrastructures were developed, aerodynamic flow instability induced wind noise or aeroacoustics became another significant design consideration, aeroacoustics became an integral part of vehicle aerodynamic design. Though drag reduction and wind noise control are the primary considerations for passenger and commercial vehicles, race cars and high-performance road and street cars require the creation of an aerodynamic downforce for better traction and cornering. Thus, aerodynamics has become the single most important aspect of race and performance vehicle designs. In addition, it is recently observed that significant drag reduction and, hence, improved fuel economy can be achieved when road vehicles are driven in convoy, called platooning; the same phenomenon is used in racing called drafting for increased speed.

Road and track testing, wind tunnel experiments, and computer simulations are the three tools of trade used in vehicle aerodynamics. All these three approaches have their advantages and limitations. Correlating results from these approaches for the same vehicle is challenging, and improving the correlations between these approaches is an ongoing process. As such, we see newer on-road and wind-tunnel measurement techniques and CFD methodologies evolving continuously. Additionally, efforts are ongoing to include the effects of real-life read road conditions, such as the impact of wind gusts or crosswind on vehicle performance, stability, and control, in laboratory environments. Over the last few decades, considerable improvements have been made in these areas, and this trend is continuing.

In consideration of the above, we have planned a Special Issue of the journal Fluids, dedicated to recent developments in experimental and modeling methodologies as applied to vehicle aerodynamics and aeroacoustics. The potential topics for submissions include but are not limited to the following broad areas: 

  • Road, train, air, and race vehicle aerodynamics;
  • Computational fluid dynamics (CFD) modeling and simulation of vehicle internal and external flows;
  • Wind tunnel testing of vehicles;
  • Road and track testing of ground vehicles;
  • Fundamentals of vehicle aerodynamics;
  • Drag reduction and flow control methodologies for vehicle flows;
  • Wind tunnel aeroacoustics measurements and testing techniques;
  • Modeling and simulations of ground vehicle aeroacoustics;
  • Wind noise reduction methodologies;
  • Road vehicle platooning and driving in proximity in racing;
  • Crosswind stability of ground vehicles;
  • Replication of on-road conditions in wind tunnel experiments;
  • CFD–wind tunnel correlation for aerodynamic and aeroacoustics measurements.

Prof. Dr. Mesbah Uddin
Guest Editor

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Keywords

  • aerodynamics and aeroacoustics of passenger and commercial road vehicles
  • aerodynamics of trains and race vehicles
  • transient aerodynamics and aeroacoustics simulations of vehicle flows
  • experimental techniques applied in road and air vehicle aerodynamics
  • flow controls applied to road and air vehicles and trains
  • aerodynamic shape optimization of vehicles
  • road vehicle overtaking maneuvers and platooning
  • effect of rapid changes in upstream flow conditions on the vehicle aerodynamic characteristics
  • interactions of vehicle flow with surrounding infrastructure

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Published Papers (7 papers)

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Research

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24 pages, 2808 KiB  
Article
Research Progress of Air Lubrication Drag Reduction Technology for Ships
by Hai An, Haozhe Pan and Po Yang
Fluids 2022, 7(10), 319; https://doi.org/10.3390/fluids7100319 - 2 Oct 2022
Cited by 6 | Viewed by 6160
Abstract
Air lubrication is a promising drag reduction technology for ships because it is considered to reduce the skin-friction resistance of ships by changing the energy of turbulent boundary layers. Air lubrication drag reduction can be classified into: microbubble drag reduction (injection of microbubbles [...] Read more.
Air lubrication is a promising drag reduction technology for ships because it is considered to reduce the skin-friction resistance of ships by changing the energy of turbulent boundary layers. Air lubrication drag reduction can be classified into: microbubble drag reduction (injection of microbubbles along the hull), air film drag reduction (using a larger film of air to cover the ship bottom), and air cavity drag reduction (recesses underneath the hull are filled with air). In this paper, the research progress of the air lubrication drag reduction technology is reviewed from experimental and numerical aspects. For these three drag reduction methods, based on the aspect of experimental research, the main research focus is the analysis and evaluation of the influencing factors such as the gas injection form and drag reduction rate; in terms of theoretical research, the accuracy of the simulation calculation depends on the selection of the theoretical calculation model and the analysis of the drag reduction mechanism. The paper introduces, in detail, the typical experimental phenomena and the theoretical results of a numerical study of three types of drag reduction methods, revealing the essence of air lubrication technology to achieve drag reduction by changing the physical properties of the turbulent boundary layer. Full article
(This article belongs to the Special Issue Aerodynamics and Aeroacoustics of Vehicles, Volume II)
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17 pages, 5663 KiB  
Article
Integration within Fluid Dynamic Solvers of an Advanced Geometric Parameterization Based on Mesh Morphing
by Ubaldo Cella, Daniele Patrizi, Stefano Porziani, Torbjörn Virdung and Marco Evangelos Biancolini
Fluids 2022, 7(9), 310; https://doi.org/10.3390/fluids7090310 - 16 Sep 2022
Cited by 1 | Viewed by 2113
Abstract
Numerical optimization procedures are one of the most powerful approaches with which to support design processes. Their implementation, nevertheless, involves several conceptual and practical complexities. One of the key points relates to the geometric parameterization technique to be adopted and its coupling with [...] Read more.
Numerical optimization procedures are one of the most powerful approaches with which to support design processes. Their implementation, nevertheless, involves several conceptual and practical complexities. One of the key points relates to the geometric parameterization technique to be adopted and its coupling with the numerical solver. This paper describes the setup of a procedure in which the shape parameterization, based on mesh morphing, is integrated into the analysis tool, accessing the grid nodes directly within the solver environment. Such a coupling offers several advantages in terms of robustness and computational time. Furthermore, the ability to morph the mesh “on the fly” during the computation, without heavy Input/Output operations, extends the solver’s capability to evaluate multidisciplinary phenomena. The procedure was preliminary tested on a simple typical shape optimization problem and then applied to a complex setup of an industrial case: the identification of the shape of a Volvo side-view mirror that minimizes the accumulation of water on the lens of a camera mounted beneath. Full article
(This article belongs to the Special Issue Aerodynamics and Aeroacoustics of Vehicles, Volume II)
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17 pages, 6183 KiB  
Article
Computational Investigation of the Aerodynamics of a Wheel Installed on a Race Car with a Multi-Element Front Wing
by Carlo Cravero and Davide Marsano
Fluids 2022, 7(6), 182; https://doi.org/10.3390/fluids7060182 - 25 May 2022
Cited by 9 | Viewed by 5862
Abstract
The search for high aerodynamic performance of a race car is one of the main aspects of the design process. The flow around the basic body shape is complicated by the presence of the rotating wheels. This is especially true in race cars [...] Read more.
The search for high aerodynamic performance of a race car is one of the main aspects of the design process. The flow around the basic body shape is complicated by the presence of the rotating wheels. This is especially true in race cars on which the wheels are not shrouded, where the effects on the flow field are considerable. Despite this, few works have focused on the flow around the rotating wheels. In this paper, CFD techniques were used to provide a detailed analysis of the flow structures generated by the interaction between a multielement inverted wing and the wheel of an open-wheel race car. In the first part, the CFD approach was validated for the isolated wheel case by comparing the results with experimental and numerical data from the literature. The wheel was analyzed both in stationary and unsteady flow conditions. Then, the CFD model was adopted to study the interaction of the flow structures between the wheel with the real grooves on the tire and the front wing of a Formula 1 car. Three different configurations were considered in order to differentiate the individual effects. The discussions were supported by the values of the aerodynamic performance coefficients and flow contours. Full article
(This article belongs to the Special Issue Aerodynamics and Aeroacoustics of Vehicles, Volume II)
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29 pages, 20806 KiB  
Article
Modeling Transport of SARS-CoV-2 Inside a Charlotte Area Transit System (CATS) Bus
by Matthew Goodson, Jeffrey Feaster, Andy Jones, Gregory McGowan, Lucas Agricola, William Timms and Mesbah Uddin
Fluids 2022, 7(2), 80; https://doi.org/10.3390/fluids7020080 - 16 Feb 2022
Cited by 4 | Viewed by 2710
Abstract
We present in this paper a model of the transport of human respiratory particles on a Charlotte Area Transit System (CATS) bus to examine the efficacy of interventions to limit exposure to SARS-CoV-2, the virus that causes COVID-19. The methods discussed here utilize [...] Read more.
We present in this paper a model of the transport of human respiratory particles on a Charlotte Area Transit System (CATS) bus to examine the efficacy of interventions to limit exposure to SARS-CoV-2, the virus that causes COVID-19. The methods discussed here utilize a commercial Navier–Stokes flow solver, RavenCFD, using a massively parallel supercomputer to model the flow of air through the bus under varying conditions, such as windows being open or the HVAC flow settings. Lagrangian particles are injected into the RavenCFD predicted flow fields to simulate the respiratory droplets from speaking, coughing, or sneezing. These particles are then traced over time and space until they interact with a surface or are removed via the HVAC system. Finally, a volumetric Viral Mean Exposure Time (VMET) is computed to quantify the risk of exposure to the SARS-CoV-2 under various environmental and occupancy scenarios. Comparing the VMET under varying conditions should help identify viable methods to reduce the risk of viral exposure of CATS bus passengers during the COVID-19 pandemic. Full article
(This article belongs to the Special Issue Aerodynamics and Aeroacoustics of Vehicles, Volume II)
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23 pages, 9142 KiB  
Article
Development of a Numerical Investigation Framework for Ground Vehicle Platooning
by Charles Patrick Bounds, Sudhan Rajasekar and Mesbah Uddin
Fluids 2021, 6(11), 404; https://doi.org/10.3390/fluids6110404 - 9 Nov 2021
Cited by 11 | Viewed by 2307
Abstract
This paper presents a study on the flow dynamics involving vehicle interactions. In order to do so, this study first explores aerodynamic prediction capabilities of popular turbulence models used in computational fluid dynamics simulations involving tandem objects and thus, ultimately presents a framework [...] Read more.
This paper presents a study on the flow dynamics involving vehicle interactions. In order to do so, this study first explores aerodynamic prediction capabilities of popular turbulence models used in computational fluid dynamics simulations involving tandem objects and thus, ultimately presents a framework for CFD simulations of ground vehicle platooning using a realistic vehicle model, DrivAer. Considering the availability of experimental data, the simulation methodology is first developed using a tandem arrangement of surface-mounted cubes which requires an understanding on the role of turbulence models and the impacts of the associated turbulence model closure coefficients on the prediction veracity. It was observed that the prediction accuracy of the SST kω turbulence model can be significantly improved through the use of a combination of modified values for the closure coefficients. Additionally, the initial validation studies reveal the inability of the Unsteady Reynolds-Averaged Navier-Stokes (URANS) approach to resolve the far wake, and its frailty in simulating tandem body interactions. The Improved Delayed Detached Eddy Simulations (IDDES) approach can resolve the wakes with a reasonable accuracy. The validated simulation methodology is then applied to the fastback DrivAer model at different longitudinal spacing. The results show that, as the longitudinal spacing is reduced, the trailing car’s drag is increased while the leading car’s drag is decreased which supports prior explanations of vortex impingement as the reason for drag changes. Additionally, unlike the case of platooning involving Ahmed bodies, the trailing model drag does not return to an isolated state value at a two car-length separation. However, the impact of the resolution of the far wake of a detailed DrivAer model, and its implication on the CFD characterization of vehicle interaction aerodynamics need further investigations. Full article
(This article belongs to the Special Issue Aerodynamics and Aeroacoustics of Vehicles, Volume II)
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19 pages, 6744 KiB  
Article
Aerodynamic Shape Optimization Method of Non-Smooth Surfaces for Aerodynamic Drag Reduction on A Minivan
by Zhendong Yang, Yifeng Jin and Zhengqi Gu
Fluids 2021, 6(10), 365; https://doi.org/10.3390/fluids6100365 - 14 Oct 2021
Cited by 7 | Viewed by 3104
Abstract
To reduce aerodynamic drag of a minivan, non-smooth surfaces are applied to the minivan’s roof panel design. A steady computational fluid dynamics (CFD) method is used to investigate the aerodynamic drag characteristics. The accuracy of the numerical method is validated by wind tunnel [...] Read more.
To reduce aerodynamic drag of a minivan, non-smooth surfaces are applied to the minivan’s roof panel design. A steady computational fluid dynamics (CFD) method is used to investigate the aerodynamic drag characteristics. The accuracy of the numerical method is validated by wind tunnel test. The drag reduction effects of rectangle, rhombus and arithmetic progression arrangement for circular concaves are investigated numerically, and then the aerodynamic drag coefficient of the rectangle arrangement with a better drag reduction effect is chosen as the optimization objective. Three parameters, that is, the diameter D of the circular concave, the width W and the longitudinal distance L among the circular concaves, are selected as design variables. A 20-level design of an experimental study using a Latin Hypercube scheme is conducted. The responses of 20 groups of sample points are obtained by CFD simulation, based on which a Kriging model is chosen to create the surrogate-model. The multi-island genetic algorithm is employed to find the optimum solution. The result shows that maximum drag reduction effects up to 7.71% can be achieved with a rectangle circular concaves arrangement. The reduction mechanism of the roof with the circular concaves was discussed. The circular concaves decrease friction resistance of the roof and change the flow characteristics of the recirculation area in the wake of the minivan. The roof with the circular concaves reduces the differential pressure drag of the front and rear of the minivan. Full article
(This article belongs to the Special Issue Aerodynamics and Aeroacoustics of Vehicles, Volume II)
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Review

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16 pages, 2983 KiB  
Review
Advances in CFD Modeling of Urban Wind Applied to Aerial Mobility
by Adrián García-Gutiérrez, Jesús Gonzalo, Deibi López and Adrián Delgado
Fluids 2022, 7(7), 246; https://doi.org/10.3390/fluids7070246 - 18 Jul 2022
Cited by 5 | Viewed by 3226
Abstract
The feasibility, safety, and efficiency of a drone mission in an urban environment are heavily influenced by atmospheric conditions. However, numerical meteorological models cannot cope with fine-grained grids capturing urban geometries; they are typically tuned for best resolutions ranging from 1 to 10 [...] Read more.
The feasibility, safety, and efficiency of a drone mission in an urban environment are heavily influenced by atmospheric conditions. However, numerical meteorological models cannot cope with fine-grained grids capturing urban geometries; they are typically tuned for best resolutions ranging from 1 to 10 km. To enable urban air mobility, new now-casting techniques are being developed based on different techniques, such as data assimilation, variational analysis, machine-learning algorithms, and time series analysis. Most of these methods require generating an urban wind field database using CFD codes coupled with the mesoscale models. The quality and accuracy of that database determines the accuracy of the now-casting techniques. This review describes the latest advances in CFD simulations applied to urban wind and the alternatives that exist for the coupling with the mesoscale model. First, the distinct turbulence models are introduced, analyzing their advantages and limitations. Secondly, a study of the meshing is introduced, exploring how it has to be adapted to the characteristics of the urban environment. Then, the several alternatives for the definition of the boundary conditions and the interpolation methods for the initial conditions are described. As a key step, the available order reduction methods applicable to the models are presented, so the size and operability of the wind database can be reduced as much as possible. Finally, the data assimilation techniques and the model validation are presented. Full article
(This article belongs to the Special Issue Aerodynamics and Aeroacoustics of Vehicles, Volume II)
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